Method and apparatus for improving sequential memory read preformance

ABSTRACT

The present technology is directed to a method for accessing a memory device in response to read requests is described. The method comprises, in response to a first request, composing a first read sequence using a command protocol of the memory device. The first read sequence includes a command code and a starting physical address. Upon receipt of a second request, the method determines a starting physical address of a second read sequence according to the command protocol of the memory device. If the starting physical address of the second read sequence is sequential to an ending physical address of the first read sequence, then the method composes the second read sequence using the command protocol without a command code, else the method composes the second read sequence using the command protocol with a read command.

TECHNICAL FIELD

This disclosure relates to memory devices and memory controllers.

DESCRIPTION OF RELATED ART

Flash memory is a class of nonvolatile integrated circuit memorytechnology. Flash memory can have a parallel interface or a serialinterface. Flash memory with a serial interface (or serial flash memory)requires fewer pin connections on a printed circuit board (PCB) thanflash memory with a parallel interface, and can reduce overall systemcost.

A host system incorporating a flash memory can read data from the flashmemory by providing a read command including an address to the flashmemory. The flash memory decodes the command and sends back datarequested by the host system. Read performance of a flash memory islimited by the speed of its interface. Read performance of a serialflash memory can be further limited because read commands and data aretransmitted to or from the serial flash memory through its serialinterface, which can be slower than a parallel interface at the sameclock rate.

It is therefore desirable to provide a method for improving readperformance of a flash memory.

SUMMARY

A method for accessing a memory device in response to read requests isdescribed. The method comprises, in response to a first request,composing a first read sequence using a command protocol of the memorydevice. The first read sequence includes a command code and a startingphysical address. Upon receipt of a second request, the methoddetermines a starting physical address of a second read sequenceaccording to the command protocol of the memory device. If the startingphysical address of the second read sequence is sequential to an endingphysical address of the first read sequence, then the method composesthe second read sequence using the command protocol without a commandcode, else the method composes the second read sequence using thecommand protocol with a read command.

Other aspects and advantages of the present technology can be seen onreview of the drawings, the detailed description and the claims, whichfollow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified block diagram of a memory.

FIG. 2 is a timing diagram illustrating a command protocol of a memory.

FIG. 3 is a block diagram of a memory controller communicating with amemory.

FIG. 4 is a flow chart of a method for producing a command sequence fora memory device in response to read requests.

FIG. 5 is a flow chart of a method for accessing a memory device inresponse to read requests.

FIG. 6 is a flow chart for a power-up sequence of a memory.

FIG. 7 is a timing diagram illustrating a method for accessing a memorydevice in response to read requests.

FIG. 8 is a block diagram of a computer system.

DETAILED DESCRIPTION

A detailed description of embodiments of the present technology isprovided with reference to the Figures.

FIG. 1 is a simplified block diagram of a memory 175 that includes logicwhich executes a sequential read operation in response to a first readcommand, including logic by which a sequential read state can be pausedor suspended. For example, the logic can pause the sequential readoperation, and hold a sequential read state during the pause. The logiccan later restart the sequential read operation without a second readcommand, thereby reducing the overhead on the channel that carriescommands to the memory 175. In this example, the memory 175 includes aserial interface through which the read commands, addresses and data arecommunicated. The serial interface can be based on a Serial PeripheralInterface (SPI) bus in which the command channel shares the I/O pinsused by address and data. For example, the memory 175 includesinput/output ports or pins 121, 122, 123, and 124 for receiving andtransmitting SPI bus signals. Pin 121 is connected to an input data linecarrying serial input data/address signal SI. Pin 122 is connected to anoutput data line carrying serial output data signal SO. Pin 123 isconnected to a clock line carrying serial clock signal SCLK. Pin 124 isconnected to a control line carrying chip enable or chip select signalCS#. The serial clock signal SCLK and chip enable signal CS# are inputsignals to the memory 175.

The memory 175 includes an array 160 of memory cells. The array 160 canhave a NOR architecture, a NAND architecture or other architectures.

An address decoder 161 is coupled to the array 160. Addresses aresupplied to the memory 175 on the pin 121 with the input signal SI andprovided to the address decoder 161. The address decoder 161 can includeword line decoders, bit line decoders, and other suitable decoders thatdecode the supplied addresses and select corresponding memory cells inthe array 160.

Bit lines in the array 160 are coupled to a page buffer 163 in thisexample, which in turn is coupled to other peripheral circuitry 174. Thepage buffer 163 can include one or more storage elements for each bitline connected. The address decoder 161 can select and couple specificmemory cells in the array 160 via respective connecting bit lines to thepage buffer 163. The page buffer 163 can then store data that is writtento or read from these specific memory cells.

Peripheral circuitry includes circuits that are formed using logiccircuits or analog circuits that are not part of the array 160, such asthe address decoder 161, the controller 140, and so on. In this example,the block 174 labeled other peripheral circuitry can includeinput-output (I/O) circuits, output data buffers, and other circuitcomponents on the memory 175, such as a general purpose processor orspecial-purpose application circuitry, or a combination of modulesproviding system-on-a-chip functionality supported by the array 160.

The controller 140 provides signals to control other circuits of thememory 175 to carry out the various operations described herein. Thecontroller 140 includes a command decoder 150 including logic supportingsequential read commands received on the serial port, and a statemachine 151 or other sequential logic circuits, including logicsupporting a paused sequential read state. The controller can beimplemented using special-purpose logic circuitry as known in the art.In other embodiments, the controller comprises a general purposeprocessor, which may be implemented on the same memory 175, whichexecutes a computer program to control the operations of the device. Inyet other embodiments, a combination of special purpose logic circuitryand a general purpose processor may be utilized for implementation ofthe controller.

A command code is supplied to the memory 175 on pin 121 according to theSPI protocol with the input signal SI and provided to the commanddecoder 150. The command decoder 150 decodes the received command code.The command decoder 150 can also set a state for the memory 175 in thestate machine 151 based on the decoded command. Based on the state inthe state machine 151, the controller 140 provides signals to addressdecoders 161, page buffer 163, the other peripheral circuitry 174, orother circuits in the memory 175 to carry out one or more operationscorresponding to the state stored in the state machine 151.

The data stored in the array 160 can be addressed in blocks of bytes orin other suitable block sizes such as blocks of 4 bytes, or blocks of 8bytes, and so on. Each block can have an address in the array 160. Ablock of data can be read from the memory 175 by providing the memory175 a read request including an address for the block of data.

The memory 175 supports a sequential read state. While in a sequentialread state, the memory 175 automatically outputs blocks of data thathave sequential addresses in the array 160 as long as the SCLK remainsactive. For example, after a first byte of data (e.g., at an address“03FFF2” in hexadecimal) is outputted from the output pin 122, thememory 175 automatically outputs a second byte of data at an address“03FFF3” that is sequential to the address of the first byte. The memorycontinues to output bytes of data at addresses that are sequential tothe addresses of previously outputted bytes (e.g., “03FFF5”, “03FFF6”,“03FFF7”, and so on) until the SCLK stops, or until the state changesout of the sequential read state, which can occur for example when thechip enable signal CS# is changed, as is described in more detail below.

The memory 175 receives and processes input data and outputs data inaccordance with a command protocol of the memory 175. FIG. 2 is a timingdiagram illustrating a command protocol of the memory 175. In thisexample, at instance 201, the chip enable signal CS# is changed fromhigh to low. When the chip enable signal CS# is held low, the memory 175is in an active mode and is available for receiving and processing inputsignals. A serial clock SCLK signal is provided to the memory 175 viathe pin 123 (at instance 202). The memory 175 inputs or outputs data bylatching input/output data bits to the serial clock SCLK.

As illustrated in the example shown in FIG. 2, during command cycles 203following the instances 201 and 202, a command code of a byte or asequence of bytes (e.g., a binary code “00000011” for a sequential readcommand) is provided to the memory 175 on the input data line connectedto the pin 121. Each bit of the command code is latched on a rising edgeof the serial clock SCLK signal (e.g., the command cycles 203 have 8clock cycles for the binary code “00000011”).

In this example, the command decoder 150 decodes the received commandcode (e.g., the binary code “00000011”) and determines that it is asequential read command. After determining the sequential read command,the command decoder 150 sets a sequential read state in the statemachine 151. Meanwhile, the command decoder 150 (or other modules of thecontroller 140) decodes the subsequent byte or bytes received via theinput data line connected to the pin 121 during the address cycles 204as a starting address for the data stored in the array 160 requested bythe sequential read command. For example, a 3-byte address (e.g.,“03FFF2” in hexadecimal) can be provided to the memory 175 via the inputdata line connected to the pin 121 during the address cycles 204. Eachbit of the 3-byte address is latched on a rising edge of the serialclock SCLK signal (i.e., the address cycles 204 have 24 clock cycles forthe 3-byte address).

In the sequential read state, the memory 175 can output datasequentially, starting with a first block of data at the startingaddress of the sequential read command. For example, the controller 140can provide the starting address and an output block size (e.g., a byte)to the address decoder 161. The address decoder 161 selects the memorycells in the array 160 that correspond to the byte at the startingaddress, and couples the selected memory cells to the page buffer 163.The controller 140 also sends control signals to the page buffer 163 andthe other peripheral circuitry 174 to send the first byte of data storedin the selected memory cells to the output pin 122. Each bit of thefirst byte of data is latched on a falling edge of the serial clock SCLKand shifted out to the output data line connected to the output pin 122.In this example, the first byte of data (“Data Out byte 1” shown in FIG.2) at the starting address (e.g., “03FFF2” in hexadecimal) of thesequential read command is outputted in 8 clock cycles during the timeperiod 205 illustrated in FIG. 2.

In the sequential read state, the memory 175 continues outputting datasequentially after the first byte of data, if the serial clock SCLK isrunning and the chip enable signal CS# is held low, without requiringadditional command and address data at the input pin 121. For example,after the first byte of data (at the address “03FFF2” in hexadecimal) isoutputted, the second byte of data at an address (e.g., “03FFF3” inhexadecimal) sequential to the address of the first byte of data isoutputted to the output pin 122. Each bit of the second byte of data islatched on a falling edge of the serial clock SCLK and shifted out tothe output data line connected to the pin 122. Here, the second byte ofdata (“Data Out byte 2” shown in FIG. 2) is outputted in 8 clock cyclesduring the time period 206 illustrated in FIG. 2.

The sequential read state can be terminated by changing the chip enablesignal CS# from low to high. When the chip enable signal CS# is heldhigh, the memory 175 is in an inactive mode and stops outputting data.The memory 175 changes state the state machine 151 out of the sequentialread state after the chip enable signal CS# is changed from low to high.

The sequential data output illustrated by FIG. 2 can be suspended bystopping the serial clock SCLK, while holding the chip enable signal CS#low. In this way, the sequential read state is pause or preserved in thestate machine 151 and the sequential data output is suspended. Thesequential data output can be resumed by resuming the serial clock SCLK.

The memory 175 can receive a command code for a sequential read commandand a starting address described above from a memory controller incommunication with the memory 175. FIG. 3 is a block diagram of a memorycontroller 310 communicating with a memory, such as the memory 175illustrated in FIG. 1. In this example, the memory controller 310communicates with the memory 175 via an SPI Bus interface 350. Thememory controller 310 includes a memory interface (I/F) 312 thatcontrols the SPI bus signals (SI input signal, SO output signal, SCLKclock, CS# signal) to and from the memory 175.

The memory controller 310 and the memory 175 can be part of a computersystem. The memory controller 310 includes a system interface (I/F) 311that communicates via a host bus with other components of the computersystem 300 such as a processor subsystem executing software programs, afile storage subsystem storing user data, and other devices andcontrollers (e.g., input/output devices, network interface devices, buscontrollers). The system interface 311 stores incoming and outgoing datain a receiving (Rx) data buffer and a transmitting (Tx) data buffer.

A controller comprising a control finite state machine (FSM) 315 in thisexample, interacts with other circuitry of the memory controller 310 tocarry out various operations, including read, program, and eraseoperations on the memory 175. In this example, information for variousoperations is stored in configuration registers such as read, program,and erase configuration registers. The control finite state machine 315carries out an operation (e.g., a read operation) on the memory 175 byaccessing information stored in a configuration register (e.g., the readconfiguration register) and causing the memory interface 312 to transmitto and receive from the memory 175 command codes and data via the SPIBus interface 350. The controller can be implemented using other typesof logic, including special-purpose logic circuitry as known in the art.In other embodiments, the controller comprises a general purposeprocessor which executes a computer program to control the operations onthe memory 175. In yet another embodiment, a combination of specialpurpose logic circuitry and a general purpose processor may be utilizedfor implementation of the controller.

Higher level applications running on processors of a computer systemincorporating the memory 175, such as an software application or a filesystem such as a disk file system (e.g., File Allocation Table or FATfile system) or a native flash file system (e.g., Journaling Flash FileSystem Version 2 or JFFS2), or a flash translation layer, can make readrequests for data stored in the memory 175. For example, a file systemcan translate the logical address of a read request (from a softwareapplication) to a physical address in the memory 175, and provide thephysical address and the size of the data requested to the memorycontroller 310 (e.g., via the host bus). The control finite statemachine 315 determines a starting physical address of the read requestas, for example, the physical address received from the file system. Inanother example, the file system can provide the logical address of theread request and the size of the data requested to the memory controller310. The control finite state machine 315 determines a starting physicaladdress of the read request by translating the logical address receivedfrom the file system to the starting physical address. The controlfinite state machine 315 also computes an ending physical address forthe read request. For example, data stored in the array 160 of thememory 175 are stored in bytes that are addressed by 3-byte addresses asdescribed earlier. If the starting physical address (of the first byteof the read request) is “10AB05” in hexadecimal while the size of thedata requested is 8 bytes, then the ending physical address (of the lastbyte of the read request) is “10AB0D” in hexadecimal.

The control finite state machine 315 then causes the memory interface312 to first set the chip enable signal CS# low. If the CS# signal isalready held low (e.g., the memory 175 is active for a previousoperation), the memory interface 312 can first set the CS# signal highand then set the CS# signal low. That is, the memory controller 310(with the memory interface 312) can end a previous operation of thememory 175 and reset the memory 175 by applying a pulse on the CS#control signal line. The memory interface 312 also starts the serialclock SCLK coupled to the memory 175. The memory interface 312 alsoprovides a command code (for a sequential read command) and the startingphysical address to the memory 175 via the SI input signals. The memory175 decodes the command code and the starting physical address, andstarts a sequential read operation. The memory 175 outputs datasequentially starting at the starting physical address as describedearlier. The memory interface 312 (e.g., as instructed by the controlfinite state machine 315) can stop the sequential read operation by forexample changing the CS# signal from low to high, which can occur afterall the bytes stored in the array 160 between the starting physicaladdress and the ending physical address are outputted by the memory 175,or upon some sorts of interruptions of the processing flow. Theoutputted bytes (i.e., the requested data) can be processed by thecontrol finite state machine 315, and passed back (via the systeminterface 311 and the host bus) to the file system running on theprocessor subsystem.

As illustrated in FIG. 2, a sequential read operation for a read requestfor data stored in the memory 175 requires an overhead of 32 clockcycles for the command code and the starting physical address of theread request, regardless of whether the size of data requested is onebyte (8 clock cycles) or 1 kilobyte (8,192 clock cycles). Thus, theaverage read performance (e.g., bytes per clock cycle) can be lower fora read request with a small requested data size (e.g., one or a fewbytes), or for a group of read requests in which each request has asmall requested data size.

However, if data requested by two or more read requests are storedsequentially in the memory 175, the data for these read requests can beread from the memory 175 sequentially with one read command and onestarting physical address. For example, a sequential read operation fora first read request can be started by providing the memory 175 a readcommand and a starting physical address for the first read request.After data for the first read request is read from the memory 175, thesequential read operation can be paused by, for example, stopping theserial clock SCLK to the memory 175 and holding the CS# signal low. If asecond read request following the first read request has a startingphysical address that is sequential to the ending physical address ofthe first request, data for the second read request can be read from thememory 175 by resuming the sequential read operation by, for example,turning on the serial clock SCLK to the memory 175 again, withoutproviding another read command and the starting physical address of thesecond read request. Data can be continuously read from the memory 175by pausing and resuming the same sequential read operation as long asdata requested by a next read request is sequential to the data of itsprevious read request. The clock cycles for the read command andstarting physical address (of the first read request) are “shared” amongthese read requests, thus improving the average read performance (e.g.,bytes per clock cycle) for each of these read requests.

FIG. 4 is a flow chart of a method for producing a command sequence fora memory device in response to read requests. The method can beimplemented by control logic controlling the memory device. In thisexample, the method can be implemented with a read access managementmodule of the memory controller 310 illustrated in FIG. 3. The readaccess management module includes a sequential read pause/resumefunction that performs pausing and resuming a sequential read operationfor multiple read requests described herein. Such implementation of themethod for accessing a memory device can be transparent to higher levelapplications running on a computer system accessing the memory device.Alternatively, the method can be implemented with software as part of afile system running on a computer system accessing the memory device.

The method of accessing a memory device in response to read requestsillustrated by the flow chart of FIG. 4 starts at Step 410. At Step 410,in response to a first request for data stored in the memory device, themethod composes a first read sequence using a command protocol of thememory device. The first read sequence includes a command code and astarting physical address.

For example, the read access management module receives a first readrequest from a host (e.g., a processor and an application running on theprocessor) of a system accessing data stored in the memory 175. Thefirst read request can include for example a starting physical addressfor data stored in the memory 175 and a size of the requested data.Based on the first read request, the read access management modulecomposes a first read sequence using a command protocol of the memorydevice. For example, the first read sequence can include a command code(e.g., the binary code “00000011” for a sequential read commanddescribed earlier) and the starting physical address (e.g., “03FFF2” inhexadecimal, where the physical address means the address as providedwith the read request directly to the memory device).

The read access management module can also calculate an ending physicaladdress for the first read request. Alternatively, the host can directlypass the starting and ending physical addresses to the read accessmanagement module.

The read access management module then causes the memory interface 312to transmit the command code and the starting physical address of thefirst read sequence to the memory 175 via the SPI Bus interface 350. Thememory 175 decodes the command code and the starting physical address,sets a sequential read state in the memory 175 (e.g., in state machine151), and performs a corresponding sequential read operation tosequentially output data stored in the memory 175, starting at thestarting physical address. For the first read request, the read accessmanagement module (via the memory interface 312) receives datasequentially outputted by the memory 175, starting at the startingphysical address of the first read sequence. The read access managementmodule passes the received data to the host (via the system interface311 and the host bus), until data at the ending physical address of thefirst read sequence is received and passed to the host.

The first read sequence ends with a pause in the sequential readoperation. The sequential read operation can be paused by stopping theserial clock SCLK to the memory 175 and holding the CS# signal low (orby another suitable signaling protocol), thus stopping sequential dataoutput by the memory 175. The read access management module for example,can then store a parameter that indicates that the memory device remainsin a paused sequential read state, along with information sufficient toidentify the ending physical address of the pause sequential readoperation.

At Step 420, upon receipt of a second read request, the methoddetermines a starting physical address of a second read sequenceaccording to the command protocol of the memory device. At Step 430, themethod determines whether the starting physical address of the secondread sequence is sequential to the ending physical address of the firstread sequence. If the starting physical address of the second readsequence is sequential to the ending physical address of the first readsequence, and the memory device remains in the sequential read state ofthe first read sequence, the method composes the second read sequenceusing the command protocol without a command code and without a startingphysical address (Step 440), by for example restarting the SCLK. TheSCLK input is separate from the address and data lines used for the readcommand and read data sequences. This enables use of the SCLK as asignaling protocol to pause and restart sequential reads. Othersignaling protocols can be utilized as well, preferably using signalingpaths that are separate from the paths used for command, address anddata flow.

Otherwise, if the starting physical address of the current read requestis not sequential to the ending physical address of the previoussequential read, the method composes the second read sequence using thecommand protocol with a read command including a command code andstarting physical address (Step 450).

For example, the read access management module receives from the host(e.g., a processor of the system accessing the memory 175 and anotherapplication running on the processor) a second read request anddetermines a starting physical address of a second read sequence. Theread access management module also calculates an ending physical addressfor the second read sequence.

The read access management module then compares the starting physicaladdress of the second read sequence and the ending physical address ofthe first read sequence. If the starting physical address of the secondread request is sequential to the ending physical address of the firstread sequence, then the read access management module composes thesecond read sequence using the command protocol without a command codeand without a starting physical address, for example with restarting theserial clock SCLK. The read access management module then, based on thesecond read sequence without a command code, causes the memory interface312 to restart the serial clock SCLK, causing the memory 175 to continuethe sequential read operation that started for the first read sequence.For the second read request, the read access management module (via thememory interface 312) receives data sequentially outputted by the memory175, starting at the starting physical address of the second readsequence. The read access management module passes the received data tothe host, until data at the ending physical address of the second readsequence is received and passed to the host.

If the starting physical address of the second read sequence is notsequential to the ending physical address of the first read sequence orthe memory device is not in a paused sequential read state, then theread access management module composes the second read sequence with thecommand protocol, with a read command (of a sequential read command).The second read sequence also includes the starting physical address ofthe second read request. The read access management module then causesthe memory interface 312 to transmit the command code and the startingphysical address to the memory 175 via the SPI Bus interface 350. Thememory 175 decodes the command code, sets a new sequential read state,and starts a corresponding sequential read operation and outputs datasequentially from the starting physical address of the second readrequest. The read access management module (via the memory interface312) receives data outputted by the memory 175 between the starting andending physical addresses for the second read request, and passes thereceived data to the host for the second read request.

The second read sequence, with or without a command code, is describedin more detail below in reference to FIG. 5.

FIG. 5 is a flow chart of a method for accessing a memory device (e.g.,the memory 175) in response to read requests. The method of FIG. 5 canbe implemented by the read access management module and other componentsof the memory controller 310 illustrated in FIG. 3. The method of FIG. 5also utilizes an address parameter that stores for example the addressof the last block of data read from the memory 175 in the currentsequential read state. The address parameter can be used to identify astarting position of a data output sequence from the memory 175. Theaddress parameter can be stored in a physical register accessible to theread access management module.

The method of FIG. 5 starts at Step 502. At Step 502, the memory 175 isset in a sequential read state. For example, the memory 175 can be setin a sequential read state while the memory 175 is powered up. This canbe a default state for environments in which a starting physical addressis known that has a likelihood of being read as a first operation onpower up, or reset, of the system, such as described with reference toFIG. 6 below.

In FIG. 5, at Step 504, the read access management module receives aread request from a host (e.g., a processor and an application runningon the processor) of the system accessing the memory 175. The readrequest includes a starting physical address and a size of datarequested. The read access management module can calculate an endingphysical address of the read request based on the starting physicaladdress and the size of data requested.

At Step 505, the read access management module determines whether thestarting physical address of the read request is sequential to thephysical address of the last block of data read from the memory 175 inthe current sequential read state. The read access management module canread address parameter stored for the ending physical address of thelast block of data read from the memory 175, and compare it with thestarting physical address of the read request.

If the starting physical address of the read request is sequential tothe physical address of the last block of data read from the memory 175in the current sequential read state, at Step 506, the read accessmanagement module causes the memory interface 312 to resume the serialclock SCLK to the memory 175. As described earlier, the memory 175resumes outputting data sequentially in the current sequential readstate after the serial clock SCLK is resumed.

As described with FIG. 4, if the starting physical address of the readrequest is sequential to the physical address of the last block of datafrom the memory 175 in the current sequential read state (i.e.,sequential to the ending physical address of the previous read request),the read sequence in response to the read request does not include acommand code or an address for a new sequential read command (Step 440).The read sequence only includes resuming the serial clock SCLK to thememory 175 (Step 506), such that the memory 175 resume outputting datasequentially in the current sequential read state, starting from thestarting physical address of the read request.

In FIG. 5, the read access management module (via the memory interface312) reads one block of data (Step 508), and determines whether allrequested data has been read from the memory 175 (Step 510). The readaccess management module starts reading the block at the startingphysical address of the read request from the memory 175 and determinesthat all requested data has been read from the memory 175 when the blockof data just read from the memory 175 has an address of the endingphysical address of the read request.

If all requested data have been read from the memory 175, at Step 512,the read access management module causes the memory interface 312 toturn off the serial clock SCLK. At Step 514, the read access managementmodule records the address of the last block of data read from thememory 175 in the address parameter. At Step 516, the memory interface312 holds the chip enable signal CS# low. By turning off the serialclock SLCK and holding the chip enable signal CS# low, the currentsequential read state is paused but maintained in the memory 175 whilethe memory 175 remains active for receiving further input, as indicatedby the loop-back from Step 516 to Step 502 shown in FIG. 5.

If the starting physical address of the read request is not sequentialto the physical address of the last block of data read from the memory175 (as determined at Step 505), the read access management module canset the memory 175 to a new sequential read state. The read accessmanagement module causes the memory interface 312 to set the chip enablesignal CS# high (Step 520). Setting the chip enable signal CS# high endsthe current sequential read state stored in the state machine 151 andplaces the memory 175 in an inactive mode. At Step 522, the read accessmanagement module causes the memory interface 312 to set the chip enablesignal CS# low, setting the memory 175 in an active mode ready forreceiving and processing input signals.

At Step 524, the memory interface 312 resumes the serial clock SCLK tothe memory 175 such that data can be transmitted to and from the memory175. At Step 526, the memory interface 312 transmits a command code (fora sequential read command) and the starting physical address of the readrequest to the memory 175. As described earlier, the command decoder 150decodes the command code and sets a new sequential read state in thestate machine 151, causing the memory 175 to start output datasequentially from the starting physical address. The read accessmanagement module sequentially reads one block of data, starting at thestarting physical address of the read request, until all data of therequest are read from the memory 175 (as illustrated by the loop ofSteps 508 and 510).

As described in FIG. 4, if the starting physical address of the readrequest is not sequential to the physical address of the last block ofdata from the memory 175 in the current sequential read state (i.e., notsequential to the ending physical address of the previous read request),the read sequence in response to the read request includes a commandcode for a new sequential read command (Step 450). As illustrated inFIG. 5, the read sequence includes applying a pulse on the chip enablesignal line (Steps 520 and 522), resuming the serial clock SCLK to thememory 175 (Step 524), and issuing a command code (for a new sequentialread command) and a starting physical address (Step 526). The readsequence causes the memory 175 to output data sequentially in a newsequential read state, from the starting physical address of the readrequest.

FIG. 6 is a flow chart for an example power-up sequence of the memory175. At Step 602, a supply voltage is provided to the memory 175 (e.g.,by the system accessing the memory 175). At Step 604, the memoryinterface 312 (e.g., as instructed by the read access management module)sets the chip enable signal CS# for the memory 175 from high to low. Asdescribed earlier, the memory 175 is active and can receive and processinput signals when the chip enable signal CS# is held low. At Step 606,the memory interface 312 turns on the serial clock SCLK input to thememory 175. At Step 608, the memory interface 312 transmits a commandcode and a default physical address (e.g., “000001” in hexadecimal) tothe memory 175 (via the input data line connected to the pin 121). Thecommand code includes a binary code for a sequential read command (e.g.,“00000011” as described earlier). After the command code and the defaultaddress are transmitted, the memory interface 312 turns off the serialclock SCLK from the memory 175 (Step 610). At Step 612, the read accessmanagement module sets the address parameter to the address one blockbefore the default address (e.g., “000000” in hexadecimal), indicatingthat the next block of data outputted from the memory 175 in an existingsequential read state will be the block of data stored at the defaultaddress in the array 160. Meanwhile, after receiving and decoding thecommand code, the command decoder 150 sets in the state machine 151 asequential read state (Step 620). With a new sequential read state and aprovided default starting physical address, the memory 175 is configuredto output data sequentially, starting at the default address of theblock of data stored in the array 160. Since the serial clock SCLK isoff immediately after the command code and the default address areprovided to the memory 175, there is no data outputted by the memory175. The memory 175 can resume outputting data sequentially, startingfrom the default address of the block of data stored in the array 160,after the serial clock SCLK is turned on again.

In an alternative embodiment, a command code for a sequential readcommand is provided to the memory 175, without providing a physicaladdress, before the serial clock SCLK is turned off. In this case, thecommand decoder 150 sets in the state machine 151 a sequential readstate that is configured to output data sequentially, starting at adefault address (e.g., “000001” in hexadecimal) in the array 160. Theaddress parameter is set to a particular value (a flag), indicating thatthe next block of data outputted with the current sequential read statewill be of the default address in the array 160, after the serial clockSCLK is turned on again.

Embodiments of the technology described herein can thus support adefault ending physical address value for the driver logic, to beutilized upon start up events, like reset or power up.

Thus FIG. 6 is an example of method for accessing a memory device inresponse to read requests, in which the read access management modulestores a parameter indicating a physical address (such as a defaultphysical address) for the memory device. In this example, upon receiptof a read request, the read access management module determines astarting physical address of a read sequence according to the commandprotocol of the memory device, and if the starting physical address ofthe read sequence matches the stored parameter, then composing the readsequence using the command protocol without a command code, elsecomposing the read sequence using the command protocol with a readcommand. The read access management module can, before receipt of saidread request, sending a command to the memory device causing the memorydevice to enter a paused sequential read state. These steps can occur onpower up or reset, causing the memory device to enter a pausedsequential read state, and setting the parameter to indicate a defaultphysical address. Also, the parameter can be determined from, or consistof, an ending physical address of a previous sequential read operation,as described above.

FIG. 7 is a timing diagram illustrating a method for accessing a memorydevice in response to read requests, such as the method illustrated byFIG. 5.

In this example, for a first read request, the chip enable signal CS# isset low (at instance 701), setting the memory 175 in an active mode. Theserial clock SCLK is on (at instance 702). A command code (for asequential read command) and a starting physical address are issued tothe memory 175 during command cycles 750 and address cycles 751,respectively. As described earlier, based on the provided command codeand starting physical address, the memory 175 is set to a sequentialread state and starts output data sequentially (starting at the startingphysical address), as illustrated by the time periods 752 and 753 shownin FIG. 7.

After data is outputted by the memory 175 for the first read request, asillustrated at the instance 703 in FIG. 7, the serial clock SCLK isstopped (Step 512), while the chip enable signal CS# is held low (Step516). Thus the sequential data output by the memory 175 is suspended.The memory 175 stays in a paused sequential read state initiated by thefirst read request (time period 754).

For a second read request, if the starting physical address of thesecond read request is sequential to the ending physical address of thefirst read request, at an instance 704, the serial clock SCLK is resumed(Step 506). Thus the memory 175 resumes outputting data sequentially,starting from the starting physical address of the second read request,as illustrated by the time periods 755 and 756 shown in FIG. 7.

For a third read request, if the starting physical address of the thirdread request is not sequential to the ending physical address of thesecond read request, as illustrated by Steps 520 and 522 of FIG. 5, thechip enable signal CS# is set high then set low, as illustrated by thepulse 705. Also, at the end of the previous sequential read, the SCLK isstopped (just before pulse 705 in this example, though the time intervalmay be any amount). The pulse 705 in the chip enable signal CS# resetsthe command decoder 150 of the memory 175. At an instance 706, theserial clock SCLK is resumed. A command code for a new sequential readcommand and the starting physical address of the third read request areissued to the memory 175 during the time periods 760 and 761,respectively. As described with the Steps 520 through 526, the memory175 is set to a new sequential read state and starts outputting datasequentially from the starting physical address of the third readrequest, as illustrated by the time period 762 in FIG. 7.

FIG. 8 is a block diagram of a computer system 810 that can include thememory controller and read access management module illustrated in FIG.3.

Computer system 810 typically includes a processor subsystem 814 whichcommunicates with a number of peripheral devices via bus subsystem 812.These peripheral devices may include a storage subsystem 824, comprisinga memory subsystem 826 and a file storage subsystem 828, user interfaceinput devices 822, user interface output devices 820, and a networkinterface subsystem 816. The input and output devices allow userinteraction with computer system 810. Network interface subsystem 816provides an interface to outside networks, including an interface tocommunication network 818, and is coupled via communication network 818to corresponding interface devices in other computer systems.Communication network 818 may comprise many interconnected computersystems and communication links. These communication links may bewireline links, optical links, wireless links, or any other mechanismsfor communication of information, but typically it is an IP-basedcommunication network. While in one embodiment, communication network818 is the Internet, in other embodiments, communication network 818 maybe any suitable computer network.

The physical hardware component of network interfaces are sometimesreferred to as network interface cards (NICs), although they need not bein the form of cards: for instance they could be in the form ofintegrated circuits (ICs) and connectors fitted directly onto amotherboard, or in the form of macrocells fabricated on a singleintegrated circuit chip with other components of the computer system.

User interface input devices 822 may include a keyboard, pointingdevices such as a mouse, trackball, touchpad, or graphics tablet, ascanner, a touch screen incorporated into the display, audio inputdevices such as voice recognition systems, microphones, and other typesof input devices. In general, use of the term “input device” is intendedto include all possible types of devices and ways to input informationinto computer system 810 or onto communication network 818.

User interface output devices 820 may include a display subsystem, aprinter, a fax machine, or non-visual displays such as audio outputdevices. The display subsystem may include a cathode ray tube (CRT), aflat panel device such as a liquid crystal display (LCD), a projectiondevice, or some other mechanism for creating a visible image. Thedisplay subsystem may also provide non visual display such as via audiooutput devices. In general, use of the term “output device” is intendedto include all possible types of devices and ways to output informationfrom computer system 810 to the user or to another machine or computersystem.

Storage subsystem 824 stores the basic programming and data constructsthat provide the functionality of certain embodiments of the presentinvention. For example, the various modules implementing thefunctionality of certain embodiments of the invention may be stored instorage subsystem 824. For example, program codes for some or all of thelogic used by the read access management module implementing the methodfor accessing a memory device described above, including the sequentialread pause/resume function, can be stored in storage subsystem 824.These software modules can be generally executed by processor subsystem814.

Memory subsystem 826 typically includes a number of memories including amain random access memory (RAM) 830 for storage of instructions and dataduring program execution and a read only memory (ROM) 832 in which fixedinstructions are stored. Memory subsystem 826 can also include a flashmemory 831 (e.g., the memory 175) which can be operated as describedherein by a memory controller including the read access managementmodule with sequential read pause/resume function. File storagesubsystem 828 provides persistent storage for program and data files,and may include a hard disk drive, a floppy disk drive along withassociated removable media, a CD ROM drive, an optical drive, orremovable media cartridges. The modules implementing the functionalityof certain embodiments of the invention may have been provided on acomputer readable medium such as one or more CD-ROMs, and may be storedby file storage subsystem 828. The host memory subsystem 826 contains,among other things, computer instructions which, when executed by theprocessor subsystem 814, cause the computer system to operate or performfunctions as described herein. As used herein, processes and softwarethat are said to run in or on “the host” or “the computer,” are executedon the processor subsystem 814 in response to computer instructions anddata in the host memory subsystem 826, including any other local orremote storage for such instructions and data.

Bus subsystem 812 provides a mechanism for letting the variouscomponents and subsystems of computer system 810 communicate with eachother as intended. Although bus subsystem 812 is shown schematically asa single bus, alternative embodiments of the bus subsystem may usemultiple busses.

Computer system 810 itself can be of varying types including a personalcomputer, a portable computer, a workstation, a computer terminal, anetwork computer, a television, a mainframe, a server farm, or any otherdata processing system or user device. Due to the ever changing natureof computers and networks, the description of computer system 810depicted in FIG. 8 is intended only as a specific example for purposesof illustrating the preferred embodiments of the present invention. Manyother configurations of computer system 810 are possible having more orless components than the computer system depicted in FIG. 8.

While the present technology is disclosed by reference to the preferredembodiments and examples detailed above, it is to be understood thatthese examples are intended in an illustrative rather than in a limitingsense. It is contemplated that modifications and combinations willreadily occur to those skilled in the art, which modifications andcombinations will be within the spirit of the technology and the scopeof the following claims.

What is claimed is:
 1. A method for accessing a memory device inresponse to read requests, comprising: in response to a first request,composing a first read sequence using a command protocol of the memorydevice, the first read sequence including a command code and a startingphysical address; and upon receipt of a second request, determining astarting physical address of a second read sequence according to thecommand protocol of the memory device, and if the starting physicaladdress of the second read sequence is sequential to an ending physicaladdress of the first read sequence, then composing the second readsequence using the command protocol without a command code, elsecomposing the second read sequence using the command protocol with aread command, wherein the memory device includes a state machineincluding a sequential read state, and the first read sequence ends witha pause in the sequential read state.
 2. The method of claim 1, whereinthe command code includes a byte or a sequence of bytes interpreted by acommand decoder on the memory device.
 3. The method of claim 1, whereinthe first read sequence includes a pulse on a control line, and thecommand code includes a byte or a sequence of bytes on one or more datalines that follow the pulse.
 4. The method of claim 3, wherein thecontrol line is a chip enable control line.
 5. The method of claim 1,wherein the first read sequence includes a pulse on a control line, andthe command code includes a byte or a sequence of bytes interpreted by acommand decoder on the memory device, and the memory device resets thecommand decoder in response to the pulse on the control line.
 6. Themethod of claim 1, wherein the sequential read state is paused by asignal protocol on a line separate from a command or data line to thememory device.
 7. The method of claim 1, wherein the sequential readstate is paused by stopping a clock signal to the memory device.
 8. Themethod of claim 7, wherein the sequential read state is resumed byresuming the clock signal to the memory device.
 9. The method of claim1, wherein the sequential read state is ended by a signal protocol on achip enable control line to the memory device.
 10. The method of claim1, wherein if the starting physical address of the second read sequenceis sequential to an ending physical address of the first read sequence,the second read sequence includes only resuming a clock to the memorydevice, causing the memory device to output data sequentially from thestarting physical address of the second read sequence, when the memorydevice is in a sequential read state.
 11. The method of claim 1, whereinif the starting physical address of the second read sequence is notsequential to an ending physical address of the first read sequence, thesecond sequence includes applying a pulse on a chip enable control line,starting a clock to the memory device, and issuing a command codeincluding the starting physical address of the second read sequence,causing the memory device to output data sequentially form the startingphysical address of the second read sequence.
 12. The method of claim 1,further comprising translating an address in a read request to aphysical address used with a read command to the memory device.
 13. Themethod of claim 1, further comprising setting the sequential read statein the state machine of the memory device without a command code andwithout a starting physical address, and pausing the sequential readstate by stopping a clock signal to the memory device.
 14. An apparatuscoupled to a memory device, the apparatus comprising: logic configuredto: in response to a first read request, compose a first read sequenceusing a command protocol of the memory device, the first read sequenceincluding a command code and a starting physical address; and uponreceipt of a second read request, determine a starting physical addressof a second read sequence according to the command protocol of thememory device, and if the starting physical address of the second readsequence is sequential to an ending physical address of the first readsequence, then compose the second read sequence using the commandprotocol without a command code, else compose the second read sequenceusing the command protocol with a read command, wherein the memorydevice includes a state machine including a sequential read state, andthe first read sequence ends with a pause in the sequential read state.15. The apparatus of claim 14, wherein the command code includes a byteor a sequence of bytes interpreted by a command decoder on the memorydevice.
 16. The apparatus of claim 14, wherein the first read sequenceincludes a pulse on a control line, and the command code includes a byteor a sequence of bytes on one or more data lines that follow the pulse.17. The apparatus of claim 16, wherein the control line is a chip enablecontrol line.
 18. The apparatus of claim 14, wherein the first readsequence includes a pulse on a control line, and the command codeincludes a byte or a sequence of bytes interpreted by a command decoderon the memory device, and the memory device resets the command decoderin response to the pulse on the control line.
 19. The apparatus of claim14, wherein the sequential read state is paused by a signal protocol ona line separate from a command or data line to the memory device. 20.The apparatus of claim 14, wherein the sequential read state is pausedby topping a clock signal to the memory device.
 21. The apparatus ofclaim 20, wherein the sequential read state is resumed by resuming theclock signal to the memory device.
 22. The apparatus of claim 14,wherein the sequential read state is ended by a signal protocol on achip enable control line to the memory device.
 23. The apparatus ofclaim 14, wherein if the starting physical address of the second readsequence is sequential to an ending physical address of the first readsequence, the second read sequence includes only resuming a clock to thememory device, causing the memory device to output data sequentiallyfrom the starting physical address of the second read sequence, when thememory device is in a sequential read state.
 24. The apparatus of claim14, wherein if the starting physical address of the second read sequenceis not sequential to an ending physical address of the first readsequence, the second sequence includes applying a pulse on a chip enablecontrol line, starting a clock to the memory device, and issuing acommand code including the starting physical address of the second readsequence, causing the memory device to output data sequentially form thestarting physical address of the second read sequence.
 25. The apparatusof claim 14, wherein the logic is further configured to translate anaddress in a read request to an address used with a read command to thememory device.
 26. The apparatus of claim 14, wherein the logic isfurther configured to set a sequential read state in a state machine ofthe memory without a command code and without a starting physicaladdress, and pause the sequential read state by stopping a clock signalto the memory device.
 27. A method for accessing a memory device inresponse to read requests, comprising: storing a parameter indicating aphysical address for the memory device; and upon receipt of a readrequest, determining a starting physical address of a read sequenceaccording to the command protocol of the memory device, and if thestarting physical address of the read sequence matches the storedparameter, then composing the read sequence using the command protocolwithout a command code, else composing the read sequence using thecommand protocol with a read command, including before receipt of saidread request, sending a command to the memory device causing the memorydevice to enter a paused sequential read state.
 28. A method foraccessing a memory device in response to read requests, comprising:storing a parameter indicating a physical address for the memory device;and upon receipt of a read request, determining a starting physicaladdress of a read sequence according to the command protocol of thememory device, and if the starting physical address of the read sequencematches the stored parameter, then composing the read sequence using thecommand protocol without a command code, else composing the readsequence using the command protocol with a read command, including onpower up or reset, causing the memory device to enter a pausedsequential read state, and setting the parameter to indicate a defaultphysical address.
 29. An apparatus coupled to a memory device, theapparatus comprising: logic configured to: store a parameter indicatinga physical address for the memory device; and upon receipt of a readrequest, determine a starting physical address of a read sequenceaccording to the command protocol of the memory device, and if thestarting physical address of the read sequence matches the storedparameter, then compose the read sequence using the command protocolwithout a command code, else compose the read sequence using the commandprotocol with a read command, wherein the logic is configured to: beforereceipt of said read request, send a command to the memory devicecausing the memory device to enter a paused sequential read state. 30.An apparatus coupled to a memory device, the apparatus comprising: logicconfigured to: store a parameter indicating a physical address for thememory device; and upon receipt of a read request, determine a startingphysical address of a read sequence according to the command protocol ofthe memory device, and if the starting physical address of the readsequence matches the stored parameter, then compose the read sequenceusing the command protocol without a command code, else compose the readsequence using the command protocol with a read command, wherein thelogic is configured to: on power up or reset, cause the memory device toenter a paused sequential read state, and set the parameter to indicatea default physical address.